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Chapter 9: Problem 27

\(\bullet\) Electric drill. According to the shop manual, when drilling a 12.7 -mm-diameter hole in wood, plastic, or aluminum, a drill should have a speed of 1250 rev/min. For a 12.7 - -mm-diameter drill bit turning at a constant 1250 \(\mathrm{rev} / \mathrm{min}\) , find (a) the maximum linear speed of any part of the bit and (b) the maximum radial acceleration of any part of the bit.

Short Answer

Expert verified
The maximum linear speed is 0.831 m/s and the maximum radial acceleration is 108.7 m/s².

Step by step solution

01

Determine the Linear Speed Formula

The linear speed \( v \) of any part of a rotating object can be calculated using the formula \( v = r \cdot \omega \), where \( r \) is the radius and \( \omega \) is the angular speed in radians per second. First, we need to convert the angular speed from revolutions per minute to radians per second.
02

Convert Angular Speed

Given that \( \omega = 1250 \) rev/min, convert this to radians per second:\[\omega = 1250 \frac{\text{rev}}{\text{min}} \times \frac{2\pi \text{ rad}}{1 \text{ rev}} \times \frac{1 \text{ min}}{60 \text{ s}} \]After calculating, \( \omega \approx 130.9 \text{ rad/s} \).
03

Calculate Maximum Linear Speed

The maximum linear speed occurs at the outer edge of the drill bit, which is half its diameter. Given the diameter is 12.7 mm, the radius \( r = \frac{12.7 \text{ mm}}{2} = 6.35 \text{ mm} = 0.00635 \text{ m} \). Now, use the formula:\[v = r \cdot \omega = 0.00635 \times 130.9 \approx 0.831 \text{ m/s}\]This is the maximum linear speed of the drill bit.
04

Determine the Radial Acceleration Formula

Radial or centripetal acceleration \( a_r \) can be calculated using the formula \( a_r = r \cdot \omega^2 \).
05

Calculate Maximum Radial Acceleration

Using the maximum radius (6.35 mm or 0.00635 m) and the angular speed (\( \omega = 130.9 \text{ rad/s} \)), calculate radial acceleration:\[a_r = r \cdot \omega^2 = 0.00635 \times (130.9)^2 \approx 108.7 \text{ m/s}^2\]This is the maximum radial acceleration of the drill bit.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Angular Velocity
Angular velocity is a crucial concept when dealing with rotational motion, such as the spinning of a drill bit. It tells us how fast an object is rotating and is usually measured in radians per second (rad/s).

In our exercise, the angular velocity, denoted by the symbol \( \omega \), is given initially in revolutions per minute (rev/min). We converted this measure into radians per second to better align with standard equations for rotational motion.

To perform this conversion:
  • First, we multiply the number of revolutions by \(2\pi\) because one full revolution is \(2\pi\) radians.
  • Then, we divide by 60 to change the time unit from minutes to seconds.
By following these steps, we found that the angular velocity of the drill bit is approximately \(130.9\) rad/s. This angular velocity helps us calculate other important aspects of the drill's motion, like linear speed and radial acceleration.
Linear Speed
Linear speed relates to how fast a point on the edge of a rotating object is traveling along a path. This speed changes with the radius of the circle created by rotation.

In the context of our drill bit, the linear speed is highest at the outermost edge. To find this speed, we use the formula \(v = r \cdot \omega\), where \(v\) is the linear speed, \(r\) is the radius, and \(\omega\) is the angular velocity.

For our drill bit:
  • The radius is half of the diameter, which means \(r = 6.35\) mm or \(0.00635\) meters when converted into meters for consistency in the units.
  • Using the angular velocity \(\omega = 130.9\) rad/s, the calculation yields a linear speed of approximately \(0.831\) m/s.
This value indicates how quickly a section on the outer edge of the drill bit is moving as the drill spins.
Radial Acceleration
Radial acceleration, also known as centripetal acceleration, is the acceleration directed toward the center of the circular path in which an object is moving. This acceleration keeps the rotating object in its circular path.

The formula for radial acceleration \(a_r\) is \(a_r = r \cdot \omega^2\). It highlights that this type of acceleration is dependent on both the radius of rotation and the square of the angular velocity.

In our example:
  • The radius of the drill bit is \(0.00635\) meters.
  • The angular velocity is \(130.9\) rad/s.
We then calculate the radial acceleration to be approximately \(108.7\, \text{m/s}^2\). This measures the rate of change of direction for a point at the drill bit's edge, which is essential for maintaining its rotational motion. Understanding radial acceleration is key to analyzing forces in rotational systems.

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Most popular questions from this chapter

\(\bullet\) (a) What angle in radians is subtended by an arc 1.50 \(\mathrm{m}\) in length on the circumference of a circle of radius 2.50 \(\mathrm{m} ?\) What is this angle in degrees? (b) An arc 14.0 \(\mathrm{cm}\) in length on the circumference of a circle subtends an angle of \(128^{\circ} .\) What is the radius of the circle? (c) The angle between two radii of a circle with radius 1.50 \(\mathrm{m}\) is 0.700 rad. What length of arc is intercepted on the circumference of the circle by the two radii?

\(\bullet\) When a toy car is rapidly scooted across the floor, it stores energy in a flywheel. The car has mass \(0.180 \mathrm{kg},\) and its fly- wheel has moment of inertia \(4.00 \times 10^{-5} \mathrm{kg} \cdot \mathrm{m}^{2} .\) The car is 15.0 \(\mathrm{cm}\) long. An advertisement claims that the car can travel at a scale speed of up to 700 \(\mathrm{km} / \mathrm{h}(440 \mathrm{mi} / \mathrm{h}) .\) The scale speed is the speed of the toy car multiplied by the ratio of the length of an actual car to the length of the toy. Assume a length of 3.0 \(\mathrm{m}\) for a real car. (a) For a scale speed of \(700 \mathrm{km} / \mathrm{h},\) what is the actual translational speed of the car? (b) If all the kinetic energy that is initially in the flywheel is converted to the translational kinetic energy of the toy, how much energy is originally stored in the flywheel? (c) What ini- tial angular velocity of the flywheel was needed to store the amount of energy calculated in part (b)?

\(\bullet\) A 7300 \(\mathrm{N}\) elevator is to be given an acceleration of 0.150 \(\mathrm{g}\) by connecting it to a cable of negligible weight wrapped around a turning cylindrical shaft. If the shaft's diameter can be no larger than 16.0 \(\mathrm{cm}\) due to space limitations, what must be its minimum angular acceleration to provide the required acceleration of the elevator?

An airplane propeller is 2.08 m in length (from tip to tip) with mass 117 kg and is rotating at 2400 rpm v about an axis through its center. You can model the propeller as a slender rod. (a) What is its rotational kinetic energy? (b) Suppose that, due to weight constraints, you had to reduce the propeller's mass to 75.0\(\%\) of its original mass, but you still needed to keep the same size and kinetic energy. What would its angular speed have to be, in rpm?

In redesigning a piece of equipment, you need to replace a solid spherical part of mass \(M\) with a hollow spherical shell of the same size. If both parts must spin at the same rate about an axis through their center, and the new part must have the same kinetic energy as the old one, what must be the mass of the new part in terms of \(M ?\)
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